JP6907596B2 - How to use groundwater - Google Patents

Description

The present invention relates to a groundwater utilization method , and more particularly to a groundwater utilization method that utilizes groundwater discharged to the ground when construction is carried out by lowering the groundwater level.

Conventionally, when constructing a foundation of a civil engineering building structure, an underground structure, or the like, a groundwater level lowering device that draws up groundwater and lowers the groundwater level at a construction site has been used (see, for example, Patent Document 1).

This groundwater level lowering device drains the well casing pipe, which is buried vertically in the ground and has a water passage part that allows the groundwater in the ground to pass through, and the groundwater collected inside the well casing pipe. It is equipped with a submersible pump, a pumping pipe for draining the groundwater absorbed by the submersible pump to the ground, and a pumping valve for adjusting the amount of pumped water.

In this groundwater level lowering device, when the pumping valve is opened, the groundwater inside the well casing pipe absorbed from the submersible pump passes through the pumping pipe and is drained to the ground, and the groundwater level in the well casing pipe is lowered.

In addition, when the groundwater level in the well casing pipe drops, the groundwater in the ground is collected inside through the water passage part formed in the well casing pipe due to the difference from the groundwater level in the ground, and this water is collected. Groundwater is sucked from the submersible pump and drained to the ground. In this way, the groundwater level inside the ground is lowered by discharging the groundwater inside the well casing pipe to the ground.

Japanese Unexamined Patent Publication No. 2007-100401

However, since the groundwater pumped by the above-mentioned groundwater level lowering device is discharged to the sewer without being used, it is required to effectively use the pumped groundwater.

An object of the present invention is to provide a groundwater utilization method capable of effectively utilizing pumped groundwater for lowering the groundwater level.

In order to achieve the above object, in the groundwater utilization method of the present invention, an excavation hole is formed in the target ground for lowering the groundwater level, and an upper opening is opened to the ground and downward with respect to the excavation hole. A hollow tubular casing pipe provided with a strainer portion for flowing groundwater of the target ground into the target ground is buried substantially vertically, and a filter layer is provided between the drilling hole and the casing pipe to form a structure. under construction is arranged a flow path which groundwater pumped in the pumping pump and before Symbol pumping pump which decreases groundwater level of the target ground by pumping groundwater on the ground to the casing pipe flows, the heat exchanger used had a row of heat exchange with the ground water flowing through the flow path, the thermal energy obtained by the heat exchange, is supplied to the installed air conditioner in a structure in the construction, completion of the structure After that, a heat collecting tube through which a heat exchange medium for heat exchange with the groundwater in the casing tube flows is arranged in the casing tube, and the upper opening of the casing tube is closed with a lid.
Then, the heat energy obtained by heat exchange between the heat exchange medium and the ground water in the casing pipe using the heat collection heat exchanger is supplied to the air conditioner installed in the completed structure. It is a feature.

According to the present invention, the groundwater pumped up to lower the groundwater level can be effectively used.

It is a schematic block diagram which shows the groundwater utilization system at the construction site where the structure which concerns on embodiment of this invention is constructing. It is a schematic block diagram which shows the groundwater utilization system after construction of the structure which concerns on embodiment of this invention. It is a figure for demonstrating the heat transfer state of the groundwater to the heat exchange medium in the buried pipe in the groundwater utilization system of FIG. 2 is a perspective view and a cross-sectional view showing a first modification of the buried pipe in the groundwater utilization system of FIG. 2. 2 is a perspective view and a cross-sectional view showing a second modification of the buried pipe in the groundwater utilization system of FIG. 2.

Hereinafter, embodiments of the groundwater utilization method of the present invention will be specifically described with reference to the drawings.

First, the groundwater utilization method according to the embodiment of the present invention will be described with reference to FIG. In the embodiment of the present invention, the groundwater utilization system used at the construction site where the structure is being constructed and the groundwater utilization system used after the structure is completed will be described.

[1. Groundwater utilization system used at construction sites under construction of structures]
First, the groundwater utilization system used at the construction site where the structure is being constructed will be described with reference to FIG. FIG. 1 is a schematic configuration diagram showing a groundwater utilization system 1 used at a construction site where a structure is being constructed.

As shown in FIG. 1, the groundwater utilization system 1 used at the construction site of the structure BL under construction includes a casing pipe 2 buried substantially vertically with respect to the target ground G for lowering the groundwater level, and a casing. A heat pump (heat) that exchanges heat between the pump 3 that pumps the groundwater W in the pipe 2 to the ground side, the flow path 4 through which the groundwater W pumped by the pump 3 flows, and the groundwater W that flows through the flow path 4. It is equipped with an exchanger) 5.

The casing pipe 2 has a hollow tubular shape made of steel, stainless steel, or the like, and is formed in an excavation hole H excavated from the ground surface of the target ground G toward the ground inside the retaining R that supports the target ground G that lowers the groundwater level. It is buried. The diameter of the excavation hole H is, for example, 500 mm to 600 mm, and the diameter of the casing pipe 2 is, for example, 300 mm to 400 mm. The length of the excavation hole H and the casing pipe 2 in the longitudinal direction X is, for example, 30 m to 40 m.

A filter layer 6 is provided between the excavation hole H and the outer peripheral surface of the casing pipe 2. The filter layer 6 is made of crushed stone and has water permeability through which groundwater W can flow. The size of the crushed stone is preferably crushed stone having a particle size of, for example, 2 mm to 3 mm, which does not pass through the strainer portion 22 of the casing pipe 2 described later.

The casing pipe 2 is provided with an opening 21 open to the ground above in the longitudinal direction X, and a strainer portion 22 into which the groundwater W of the target ground G flows into the inside below in the longitudinal direction X. It is provided. The strainer portion 22 is configured by, for example, covering a plurality of slit-shaped through holes with a mesh material or winding the strainer portion 22 with a coil. The strainer portion 22 allows the groundwater W in the target ground G to pass through the inside of the casing pipe 2 and prevents the particles of the target ground G and the filter layer 6 from flowing into the inside of the casing pipe 2.

The pump 3 is provided at the bottom of the casing pipe 2 and is a pump that absorbs the groundwater W that has flowed into the casing pipe 2 via the strainer portion 22.

The flow path 4 includes a pumping pipe 41 through which the groundwater W absorbed by the pump 3 flows, a heat exchange path 42 through which the groundwater W supplied to the heat pump 5 side flows, and groundwater W whose heat is exchanged by the heat pump 5. It is provided with a first supply path 43 through which the groundwater W supplied to the water flows. The first supply passage 43 is branched into a second supply passage 44 (washing water supply passage) and a third supply passage (miscellaneous water supply passage) 45.

The pumping pipe 41 has one end connected to the pumping pump 3 and the other end connected to the filtration filter 8, and is a flow path through which the groundwater W sucked by the pumping pump 3 and pumped to the ground side flows.

The heat exchange path 42 is a flow path through which the groundwater W filtered by the filtration filter 8 and sent to the heat pump 5 flows.

The first supply path 43 is a flow path through which the groundwater W whose heat has been exchanged by the heat pump 5 flows.

The second supply path 44 is a flow path through which the groundwater W through which heat exchange has been performed is sent to the cleaning nozzle 10. The cleaning nozzle 10 is a nozzle used for cleaning the solar panel 7b that covers the solar cell 7a of the photovoltaic power generation device 7 that supplies electric power to a predetermined building. The predetermined building is a building such as a site office constructed in a construction site where a structure is constructed on the target ground G (hereinafter, referred to as a site building OF).

The third supply path 45 is a flow path through which the groundwater W through which heat exchange has been performed is sent to the spray nozzle 11. The spray nozzle 11 is a nozzle that sprays groundwater W as miscellaneous water, and for example, sprays groundwater W as mist or sprinkling water in a construction site of a structure BL under construction.

The heat pump 5 is a device that exchanges heat between the groundwater W flowing through the heat exchange path 42 and the heat exchange medium F1 flowing through the circulation path 13 connected to the air conditioner 12 installed in the site building OF. The heat exchange medium F1 is a liquid or gas such as water or antifreeze (for example, ethylene glycol).

In this groundwater utilization system 1, the groundwater W in the casing pipe 2 absorbed by the pump 3 is pumped through the pump pipe 41. When the water level WL in the casing pipe 2 drops below the groundwater level S1 of the target ground G, the groundwater W flows into the casing pipe 2 from the strainer portion 22 in the direction of arrow A. Then, while the pump 3 absorbs the groundwater W in the casing pipe 2, the groundwater level S1 of the target ground G drops. In this way, the groundwater W in the casing pipe 2 is absorbed by the pump 3 to lower the groundwater level S1 of the target ground G to the groundwater level S2, that is, the groundwater W is discharged from the target ground G or is generated by the so-called deep well method. Construct the structure with the board swelling prevented.

Further, the groundwater W flowing through the pumping pipe 41 is filtered by the filtration filter 8 and sent to the heat pump 5. The groundwater W sent to the heat pump 5 is heat-exchanged with the heat exchange medium F1, and the groundwater W whose temperature has been lowered or raised by the heat exchange is passed through the first supply passage 43 to the second supply passage 44 or the third. It is sent to the supply channel 45.

According to the groundwater utilization system 1, the groundwater W whose heat has been exchanged by the heat pump 5 is sent from the second supply path 44 to the cleaning nozzle 10 to clean the solar panel 7b, so that the groundwater level S1 can be lowered. The pumped groundwater W can be effectively used.

Normally, when constructing the structure BL, the groundwater W is pumped up from the target ground G on which the structure BL is constructed to prevent the groundwater W from springing out or swelling, and the work is performed while lowering the groundwater level S1. It is carried out. Then, the large amount of groundwater W pumped up is discharged to the sewer for a fee.

However, according to this groundwater utilization system 1, heat is exchanged between the groundwater W in the casing pipe 2 absorbed by the pump 3 and the heat exchange medium F1, so that the heat of the groundwater W is used for air conditioning of the site building OF. By using it for the machine 12, it is possible to reduce the power consumption of the air conditioner 12. Therefore, by using the thermal energy of the groundwater W, it is possible to reduce the power consumption at the construction site.

Further, in the groundwater utilization system 1, the groundwater W whose heat has been exchanged by the heat pump 5 is sent from the second supply path 44 to the cleaning nozzle 10 to clean the solar panel 7b, so that dust adhering to the solar panel 7b and dust It is possible to suppress a decrease in the power generation efficiency of the solar cell 7a due to dust and efficiently supply electric power to the on-site building.

Further, in the groundwater utilization system 1, the groundwater W whose heat has been exchanged by the heat pump 5 is sent from the third supply path 45 to the spray nozzle 11 and sprayed into the construction site as mist or sprinkling water. It is possible to suppress the heat island phenomenon caused by the heat radiated into the atmosphere.

[2. Groundwater utilization system used after the structure is completed]
Next, the groundwater utilization system 50 to be used after the completion of the structure will be described with reference to FIGS. 2 and 3. FIG. 2 is a schematic configuration diagram showing a groundwater utilization system 50 that will be used after the structure BL is completed. FIG. 3 is a diagram for explaining a state in which the heat of the groundwater W is transferred to the heat exchange medium F2 in the casing pipe 2 in the groundwater utilization system 50.

In the groundwater utilization system 50 used after the completion of the following structures, the casing pipe 2 buried in the target ground G in the groundwater utilization system 1 during the construction of the above-mentioned structure BL is used after the completion of the structure BL. It is also used for the structure BL'.

As shown in FIG. 2, the groundwater utilization system 50 used in the completed structure BL'is the above-mentioned casing pipe 2 and a heat exchange medium disposed in the casing pipe 2 to exchange heat with the groundwater W. A heat collection tube 51 through which F2 flows and a heat pump 52 that exchanges heat between the heat exchange medium F2 are provided.

Further, the groundwater utilization system 50 is connected to a pump device 53 provided in the heat collection tube 51 to send the heat exchange medium F2 to the heat pump 52 and a circulation path 54 through which the heat exchange medium F3 flows, and the heat pump is connected via the heat exchange medium F3. The air conditioner 55 is provided with the heat collected by the 52. The heat exchange media F2 and F3 are liquids or gases such as water and antifreeze (for example, ethylene glycol).

The casing pipe 2 is buried in the excavation hole H of the target ground G in the completed structure BL', and the opening 21 (see FIG. 1) open to the ground is closed above in the longitudinal direction X. A lid 56 is provided. That is, the casing pipe 2 is a closed casing pipe in which the above-mentioned opening 21 is closed by a lid 56. Since the above-mentioned pumping pump 3 cannot be maintained in the closed casing pipe, the groundwater utilization system 50 removes the pumping pump 3 and installs a pump device 53 in place of the pumping pump 3.

The heat collection tube 51 is, for example, a U-shaped hollow tube made of high-density polyethylene resin and penetrating the lid 56, and the circulation path 57a in which the heat exchange medium F2 circulates between the casing tube 2 and the heat pump 52. , 57b.

The circulation path 57a is an outward pipe through which the heat exchange medium F2 is sent to the heat pump 52 side, and the circulation passage 57b is a return pipe through which the heat exchange medium F2 is sent to the casing pipe 2 side. The heat collection tube 51 is arranged as a set of a circulation path 57a which is an outward path tube and a circulation path 57b which is a return path tube, but the circulation path 57a which is an outward path tube and the circulation path 57b which is a return path tube are arranged. Two or more sets may be arranged.

The heat pump 52 is a device that exchanges heat between the groundwater W flowing through the heat collection tube 51 and the heat exchange medium F3 flowing through the circulation path 54 connected to the air conditioner 55 installed in a predetermined structure. The predetermined structure is the completed structure BL'completed by the construction for constructing the above-mentioned structure BL.

As shown in FIG. 3, in the groundwater utilization system 50, the heat exchange medium F2 that has been heated or lowered by flowing through the heat collecting pipe 51 and exchanging heat with the groundwater W in the casing pipe 2 is driven by the pump device 53. It flows through the circulation path 57a and is sent to the heat pump 52. The heat exchange medium F2, which has undergone heat exchange by the heat pump 52, flows through the circulation path 57b and returns to the inside of the casing pipe 2.

In this groundwater utilization system 50, since the periphery of the heat collection pipe 51 in the casing pipe 2 is groundwater W, the heat collection efficiency is higher than the case where the heat collection pipe 51 is buried in the target ground G and the underground heat is used. That is, since the ground water W flowing from the strainer portion 22 is convected in a predetermined direction (for example, the direction of arrow B) in the casing pipe 2, convection heat transfer is performed in contrast to the case of solid heat transfer using geothermal heat. Therefore, the heat exchange medium F2 can be heated or lowered more quickly.

Further, in this groundwater utilization system 50, since the groundwater W is advected in a predetermined direction (for example, the direction of arrow C) in the target ground G, the heat exchange medium F2 is faster than the case of solid heat transfer using geothermal heat. Can be raised or lowered.

According to the groundwater utilization system 50, the opening 21 (see FIG. 1) of the casing pipe 2 buried in the excavation hole H excavated in the target ground G in the above-mentioned groundwater utilization system 1 is closed, and the groundwater W is formed by the heat sampling pipe 51. Since the heat energy of the above is used, the casing pipe 2 can be effectively used as it is.

Normally, a well such as a casing pipe 2 buried for pumping up the groundwater W when constructing the structure BL closes the opening 21 and remains buried when the construction for constructing the structure BL is completed. However, as described above, in the groundwater utilization system 50, the casing pipe 2 after the construction for constructing the structure BL is completed is used as it is, and the heat collection pipe 51 is arranged in the casing pipe 2 to heat the groundwater W. In order to utilize the energy, the thermal energy of the groundwater W can be supplied to the air conditioner 55 of the completed structure BL'.

Further, in the groundwater utilization system 50, since the heat collection pipe 51 is arranged for the casing pipe 2 for which the construction has been completed, the heat energy of the groundwater W is supplied to the air conditioner 55 of the completed structure BL'. As additional equipment, only the heat collection tube 51 and the heat pump 52 are arranged and connected. Therefore, excavation work or the like for burying a pipe for newly arranging the heat collecting pipe 51 becomes unnecessary.

Further, in the groundwater utilization system 50, since the periphery of the heat collection pipe 51 in the casing pipe 2 is the groundwater W, good heat exchange is performed between the groundwater W and the heat exchange medium F2, and the heat exchange medium F2 is used. Heat exchange is performed with the heat exchange medium F3. Therefore, in the groundwater utilization system 50, the heat energy of the groundwater W can be efficiently collected, and the heat energy of the groundwater W can be efficiently utilized in the air conditioner 55, so that the power consumption of the air conditioner 55 can be reduced. It is possible to reduce it.

Next, the first and second modifications of the groundwater utilization system 50 described above will be described with reference to FIGS. 4 and 5. The first modification and the second modification are different from the structure of the heat collection tube 51 of the groundwater utilization system 50 of FIG. In the first and second modified examples, the same components as the groundwater utilization system 50 of FIG. 2 are designated by the same reference numerals, and different parts will be described.

FIG. 4A is a perspective view of the heat collection tube 61 showing a first modification of the heat collection tube 51, and FIG. 4B is a cross section taken along the line AA shown in FIG. 4A. It is a figure. As shown in FIGS. 4 (a) and 4 (b), the heat collection tube 61 in the first modification has four circulation paths 62a, 62b, 62c, 62d along the longitudinal direction X direction and one. It is composed of the circulation path 63 of. The four circulation paths 62a, 62b, 62c, and 62d are outward pipes that send the heat exchange medium F2 to the heat pump 52 side, and the circulation passage 63 is a return pipe that sends the heat exchange medium F2 to the casing pipe 2 side.

Of the circulation paths 62a, 62b, 62c, 62d and the circulation path 63, the circulation path 63 is arranged at the center of the plane in the casing pipe 2 (for example, the center of FIG. 4B), and the remaining four circulation paths 62a , 62b, 62c, 62d are arranged so as to surround the circulation path 63. That is, the circulation paths 62a, 62b, 62c, and 62d are arranged at equal intervals so as to surround the circulation path 63 and approach the inner peripheral surface side of the casing pipe 2.

The heat exchange medium F2 flowing through the heat collection pipe 61 rises or falls in temperature by exchanging heat with the groundwater W in the casing pipe 2, and then flows through the circulation passages 62a, 62b, 62c, 62d to the heat pump 52 ( (See Fig. 2). Then, heat exchange is performed with the heat exchange medium F3 in the heat pump 52, and the heat exchange medium F2 whose temperature has been lowered or raised flows through the circulation path 63 and returns to the inside of the casing pipe 2.

According to the heat collection tube 61, the circulation path 63 is arranged at the center of the plane in the casing tube 2, and the circulation paths 62a, 62b, 62c, 62d surround the circulation path 63 and approach the inner peripheral surface side of the casing tube 2. Since they are arranged at equal intervals, the distance between the circulation paths 62a, 62b, 62c, and 62d with respect to the circulation path 63 can be increased, and the distance between the circulation paths 62a, 62b, 62c, 62d and the circulation path 63 can be increased. It is possible to suppress the short circuit where heat is transferred and improve the heat exchange efficiency.

Further, the circulation passages 62a, 62b, 62c, 62d, which are the outward pipes to which the heat exchange medium F2 is sent to the heat pump 52 side, are compared with the circulation passages 63, which are the return pipes to which the heat exchange medium F2 is sent to the casing pipe 2 side. Since the number of pipes is large, the area for heat exchange with the groundwater W (see FIG. 2) can be expanded, and the heat exchange efficiency can be further improved.

FIG. 5A is a perspective view of the heat collection tube 71 showing a second modification of the heat collection tube 51, and FIG. 5B is a cross section taken along the line BB shown in FIG. 5A. It is a figure.

As shown in FIGS. 5 (a) and 5 (b), the heat collection tube 71 in the second modification has a circulation path 73 including three circulation paths 72a, 72b, 72c along the longitudinal direction X direction. , The circulation path 74. In other words, the circulation path 73 is branched into three pipelines of circulation paths 72a, 72b, and 72c. The circulation path 73 is an outward pipe that sends the heat exchange medium F2 to the heat pump 52 side, and the circulation passage 74 is a return pipe that sends the heat exchange medium F2 to the casing pipe 2 side.

The circulation paths 72a, 72b, 72c and the circulation paths 74 are arranged at equal intervals close to the inner peripheral surface side of the casing pipe 2, respectively.

The heat exchange medium F2 flowing through the heat collection pipe 71 rises or falls in temperature by exchanging heat with the groundwater W in the casing pipe 2, and then flows through the circulation passages 72a, 72b, 72c and joins in the circulation passage 73. Is sent to the heat pump 52 (see FIG. 2). Then, heat exchange is performed with the heat exchange medium F3 by the heat pump 52, and the heat exchange medium F2 whose temperature has been lowered or raised flows through the circulation path 74 and returns to the inside of the casing pipe 2.

According to the heat collection pipe 71, the circulation passages 72a, 72b, 72c and the circulation passages 74 are arranged at equal intervals close to the inner peripheral surface side of the casing pipe 2, respectively, and thus the circulation passages 72a, 72b, 72c. The distance between the circulation paths 74 can be increased, and the short circuit in which heat is transferred between the circulation paths 72a, 72b, 72c and the circulation path 74 can be suppressed to improve the heat exchange efficiency.

Further, the number of circulation paths 72a, 72b, 72c, which are the outbound pipes through which the heat exchange medium F2 is sent to the heat pump 52 side, is larger than that of the circulation passage 74, which is the return pipe through which the heat exchange medium F2 is sent to the casing pipe 2 side. Therefore, the area for heat exchange with the ground water W (see FIG. 2) can be expanded, and the heat exchange efficiency can be further improved.

[3. Other embodiments]
In the groundwater utilization system 1 in the above-described embodiment, the case where the casing pipe 2 is buried inside the retaining R is described, but even if the casing pipe 2 is embedded in the target ground G outside the retaining R. good.

Further, in the groundwater utilization system 1 in the above-described embodiment, the case where the groundwater W for which heat exchange has been performed is sent to the cleaning nozzle 10 for cleaning the solar panel 7b of the photovoltaic power generation device 7 that supplies electric power to the site building. As explained, but not limited to this. For example, the heat-exchanged groundwater W may be sent to a cleaning nozzle for cleaning the solar panel of the photovoltaic power generation device that supplies electric power to the building constructed outside the site where the structure BL is constructed.

Further, in the groundwater utilization system 1 in the above-described embodiment, the case where the groundwater W after heat exchange is sent to the spray nozzle 11 which is sprayed as mist or sprinkling water in the site where the structure BL is constructed has been described. Not limited to this. For example, the groundwater W to be sent to the spray nozzle 11 may be the groundwater W after cleaning the solar panel 7b, or the groundwater W may be sent to the spray nozzle to be sprayed as mist or sprinkling water outside the site.

Further, in the groundwater utilization system 1 in the above-described embodiment, the configuration in which the thermal energy of the groundwater W is used for the air conditioner 12 installed in the site building OF has been described, but further, the thermal energy of the groundwater W is used in the site building OF. It may be configured to be used in other equipment such as an installed water heater and a snow melting device set in the site. Further, it may be used for a device in which one or more of these devices are combined.

Further, in the groundwater utilization system 50 in the above-described embodiment, the configuration in which the thermal energy of the groundwater W is used for the air conditioner 55 installed in the structure BL'after completion has been described. It may be configured to be used in other equipment such as a water heater installed in the completed structure BL'and a snow melting device installed in the completed structure BL'. Further, it may be used for a device in which one or more of these devices are combined.

Although the embodiments of the present invention have been described above, the present invention is not limited to the groundwater utilization systems 1, 50 according to the above-described embodiments, and all aspects included in the concept of the present invention and the scope of claims are included. include. In addition, each configuration may be selectively combined as appropriate so as to achieve at least a part of the above-mentioned problems and effects.

1 Groundwater utilization system 2 Casing pipe 3 Pumping pump 4 Flow path 5 Heat pump (heat exchanger)
6 Filter layer 7 Photovoltaic power generation device 7a Solar cell 7b Solar panel 8 Filtration filter 10 Cleaning nozzle 11 Spray nozzle 12 Air conditioner 13 Circulation path 21 Opening 22 Strainer section 41 Pumping pipe 42 Heat exchange path 43 First supply path 44 No. 2 Supply path 45 Third supply path 50 Ground water utilization system 51 Heat collection tube 52 Heat pump 53 Pump device 54 Circulation path 55 Air conditioner 56 Lid 57a, 57b Circulation path 61 Heat collection tube (first modification)
62a, 62b, 62c, 62d circulation path (first modification)
63 Circulation path (first modification)
71 Heat collection tube (second modification)
72a, 72b, 72c circulation path (second modification)
73 Circulation path (second modification)
74 Circulation path (second modification)
BL structure F1, F2, F3 Heat exchange medium G Target ground H Drilling hole OF Site building R Mountain retaining S1 Groundwater level S2 Groundwater level W Groundwater WL Water level

Claims (6)

An excavation hole was formed in the target ground for lowering the groundwater level, and an upper opening was opened to the ground with respect to the excavation hole, and a strainer portion was provided below for the groundwater of the target ground to flow into the inside. A hollow tubular casing pipe is embedded substantially vertically, and a filter layer is provided between the excavation hole and the casing pipe.
During the construction of the structure
The groundwater is disposed between the ground-side flow path pumped groundwater flows by pumping to pump - the previous SL pumping pump which decreases groundwater level of the target ground to the casing pipe, the flow by using a heat exchanger There line exchanges heat with the ground water flowing through the road, the thermal energy obtained by the heat exchange, is supplied to the installed air conditioner in a structure in the construction,
After the structure is completed,
A heat collecting tube through which a heat exchange medium for heat exchange with the ground water in the casing pipe flows is arranged in the casing pipe, and the upper opening of the casing pipe is closed with a lid, and a heat collecting heat exchanger is used. groundwater wherein the supplying thermal energy obtained by the heat exchange with the groundwater of the casing pipe and the heat exchange medium, in the installed air conditioner structure after the completion. The heat collection tube is
A return pipe that extends in the longitudinal direction of the casing pipe and through which the heat exchange medium from the heat collection heat exchanger flows.
It has an outbound pipe that extends in the longitudinal direction of the casing pipe and through which a heat exchange medium flows toward the heat collection heat exchanger.
The lower end of the return pipe and the lower end of the outward pipe are connected by a pipe extending radially from the center of the plane of the casing pipe to a position in contact with the inner peripheral surface of the casing pipe.
The method for using groundwater according to claim 1, wherein the groundwater is used. One of the return pipe and the outward pipe is arranged in the center of the plane.
The rest of the return pipe and the outward pipe are arranged so as to be in contact with the inner peripheral surface of the casing pipe and are provided at equal intervals in the circumferential direction of the casing pipe.
The method for using groundwater according to claim 2, wherein the groundwater is used. The return pipe and the outward pipe are arranged so as to be in contact with the inner peripheral surface of the casing pipe and are provided at equal intervals in the circumferential direction of the casing pipe.
The method for using groundwater according to claim 2, wherein the groundwater is used. A claim characterized by further including a washing water supply path for supplying groundwater pumped by the pump to a washing nozzle for washing a solar panel covering a solar cell of a photovoltaic power generation device that supplies electric power to a predetermined building. Item 8. The method for using groundwater according to any one of Items 1 to 4. The method for using groundwater according to any one of claims 1 to 5 , further comprising a miscellaneous water supply channel for supplying the groundwater pumped by the pump as miscellaneous water.

Images